Python Recipes for Engineers and Scientists: Scripts that devour your integrals, equations, differential equations, and interpolations!

This book is not a manual of PYTHON nor does it replace many excellent books on the use of this cool language. What this book offers is a friendly aid for some of the frequent numerical problems that arise in the analytical study of many engineering and physical problems. The chapters of the book reach the point in a simple way by deliberately giving up to impress the reader with the power and sophistication of PYTHON in favor of readability and understanding. The scripts are autonomous and solve very specific problems such as interpolation and fitting, non-linear equations, integration, differential equations, in few essential sentences. Even so, the reader will see that they can combined and adapt to real problems.I assumed that the reader has some elementary knowledge of script writing, although not necessarily advanced knowledge. Yet, a Python primer is included at the end.

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Python Recipes for Engineers and Scientists Scripts that devour your Integrals, Equations, Differential equations, and Interpolations!

Javier Riverola Gurruchaga

.

2

.

To my wife and sons, Dolores, Javier and Diego, for their support and good advice

4

Contents Introduction . . . . . . . . . . . . . . . . . . . . . 1

Interpolation and Fitting 1.1 Linear Interpolation . . . . . . . . 1.2 Pure Polynomial Interpolation . . 1.3 Cubic Splines . . . . . . . . . . . 1.4 Example of Interpolation Methods 1.5 Least Squares . . . . . . . . . . .

7

. . . . .

11 12 13 14 16 18

2

Integration 2.1 Symbolic Integration . . . . . . . . . . . . . 2.2 Numerical Integration . . . . . . . . . . . . .

23 23 25

3

Solving equations 3.1 Systems of Linear Equations . . . . . . . . . 3.2 Systems of non-linear Equations . . . . . . .

35 35 37

4

Differential Equations 4.1 Ordinary Differential Equations . . . . . . . 4.2 Partial Differential Equations . . . . . . . . .

41 41 44

5

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CONTENTS 5

6

7

CONTENTS

Mathematical Statistics 5.1 Mean and Standard Deviation . 5.2 Confidence Limits of µ and σ 2 5.3 Population Bounds . . . . . . 5.4 Test for a Distribution . . . . . Proposed Exercises 6.1 Complex Pendulum . . . . . 6.2 Pressure Drop in a Pipe . . . 6.3 The Butterfly Effect . . . . . 6.4 "Out of the Box" . . . . . . 6.5 Listen to that whale! . . . . 6.6 Calculate π with Montecarlo

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Answers to Problems 7.1 Answer to Complex Pendulum . . . . . 7.2 Answer to Pressure Drop in a Pipe . . . 7.3 Answer to The Butterfly Effect . . . . . 7.4 Answer to "Out of the Box" . . . . . . . 7.5 Answer to Listen to that Whale! . . . . 7.6 Answer to Calculate π with Montecarlo

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49 49 51 53 54

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57 57 58 59 61 63 64

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67 67 69 70 71 75 78

A Python Primer

81

B Packages Contents

99

6

Introduction Dear reader, this book is not a Python manual. It does not replace the many excellent books on the use of this cool language. There are tons of information on the Internet (tutorials, manuals, users groups, examples), so it is alive and accessible from any computer with connection to The Web1 . Nor is it an exhaustive compendium of calculation options that covers the many possible problems with which an engineering student or professional is met. What this book provides is a friendly help to some of the frequent numerical problems that arise in the analytical study of many engineering and physical problems. The chapters of the book get to the point in a simple way by deliberately renouncing to impress the reader with the ultra-power and sophistication of Python in favor of readability and comprehension. The included miniscripts are autonomous and solve very specific problems and the reader will see that they can be combined and adapted to real problems. In a way, this is the cookbook that I would have liked to 1

Good reference sites are http://www.Python.org, Python Programming in Wikibooks https://en.wikibooks.org/wiki/Main_Page, or the excellent books like “Automate the Boring Stuff with Python” by Al Sweigart.

7

CONTENTS

CONTENTS

have in my graduate and undergraduate courses and that I dare to write now after quite a few years of engineering work in which the quick solution of problems was a necessity and it remains so. Really, the simple and the practical is what remains after your being in trouble sometimes. For simplicity, I assumed that the reader has some basic knowledge of writing scripts: write a formula, create and manipulate arrays, plot simple graphs, import modules such as numpy, scipy, and matplotlib, ... although not necessarily advanced knowledge. It is not a book for specialists. I have selected the topics ordered according to a postgraduate course in numerical methods (interpolation, differential equations, integration, etc.), avoiding all the theoretical apparatus and leaving only what is useful and essential, without entering into other topics such as optimization, treatment of images, creation of operating systems, etc. In addition to the recipes, the reader is challenged at the end of the book with some interesting exercises with the dual purpose of reviewing and escaping from boring life: identify a whale by singing, calculate pi with unorthodox methods, solve the Schrodinger equation, and so on. Over many years I have tried different programming languages from Assembler, Fortran, Matlab / Octave, and the like, but I have found in Python a freshness and a dynamism very much in line with these times. It is even an element of free conversation with the new generation of professionals, for example with one of my sons, also an engineer, and friends. You may know that the Zen of Pyton is (Tim Peters2 ): Beautiful is better than ugly. 2

Easter egg: try in Python console >import this

8

CONTENTS

CONTENTS

Explicit is better than implicit. Simple is better than complex. Complex is better than complicated. Readability counts. I have enjoyed writing this book and I hope that you will also enjoy it and that it will be of benefit to you in your studies and professional life. Javier Riverola

9

CONTENTS

CONTENTS

10

1 | Interpolation and Fitting There are many occasions in Engineering and Science in which it is necessary to interpolate an unknown y value for a given x among pairs of values (x0 ,y0 ),..., (xn ,yn ). For instance, this might be the case that we require a thermophysical property of a material (conductivity, density, ...) but we have only tables with a few pairs of values, or perhaps it might be the case that we need to estimate a credible result between actual results of a test or calculations, and that sort of things. Interpolation is a kind of routine task but you ought to be careful to avoid unpleasant surprises. There is a suitable method of interpolation for each situation, depending on the risk that you want to assume, and on whether you can infer in advance some smooth or abrupt behavior, or on your knowledge of trends at the extremes of the interval of interpolation. We will explore some of these possibilities in this chapter. 11

Linear Interpolation

Interpolation and Fitting

I wonder what the y value is!

1.1

Linear Interpolation

Linear interpolation is useful when, according to a conservative strategy, you do not want to take risks, even at the cost of giving up on obtaining a more accurate prediction. There are many cases in which this way of proceeding is the most appropriate. The idea is quite simple: just find the interval i that contains the x value to interpolate, an draw a straight line passing through both extremes of the interval, so you can estimate the y value. fi+1 − fi xi+1 − xi This is done easily in Python with: y = interp(x, xdata, ydata) y ' fi + (x − xi )

We obtain the same result with: y = float(interp1d(xdata, ydata,’linear’)(x)) 12

Interpolation and Fitting

Pure Polynomial Interpolation

The latter form is more sophisticated, but more interesting because one can change easily from ’linear’ to ’quadratic’, or ’cubic’, as needed. The Examples subsection includes some of these options.

1.2

Pure Polynomial Interpolation

We search for a polynomial that passes thru all n+1 points, y = a0 + a1 x + a2 x2 + ... + an xn so we can interpolate y' Pn (x). We can write the linear system of equations as a matrix system:       y0  1 x0 x20 ... xn0   a0        n     1 x1 ... . x1  .. y1   =   .. ..    . .          n   1 ... xn an yn  Now, we can obtain the unknown coefficients immediately as follows: {a} = [X]−1 · {Y } However, this system is ill conditioned with both small and large number together and rounding errors may emerge and ruin the outcome. There is a number of popular techniques to calculate ai without the need to solve the system such as the Newton’s, Langrange’s, and Aitken’s interpolation methods. 13

Cubic Splines

Interpolation and Fitting

But, we will bypass all them, and we will let Python do the job as follows: y = poly1d(polyfit(xdata,ydata,len(xdata)-1))(x) It seems tricky but it works. Besides, if you need the values of the polynomial coefficients, then just run: c = polyfit(xdata, ydata, len(xdata)-1) where c array is ordered from highest to lowest degree term (an , ...a0 ). Warnings! / Pure polynomial may oscillate especially near extremes, and near to abrupt changes in data trends. For this rease, a polynomial larger than fifth degree is rarely used. If there are many data points, it is better to perform interpolations based on least squares fit or splines, as explained in next section. / Besides, it is not recommended to use a pure polynomial for extrapolating purposes, that is, to obtain results out of the [x0 , xn ] range. If you cannot escape from extrapolating, then you should perform a linear extrapolation instead.

1.3

Cubic Splines

A spline is a differentiable curve defined in portions by polynomials. It is an interpolation method consisting of dividing the set of points into pieces ensuring continuity, which has many advantages and it has a correspondence with many physical phenomena. We can imagine a spline as a flexible and resistant rod that passes through each of the data points in a smooth 14

Interpolation and Fitting

Cubic Splines

manner. Here, we are going to sketch only the most relevant spline formulation, which is the cubic spline with continuous second derivative (C 2 ). If our data points are (x0 , y0 ). . . (xn , yn ), the spline is a cubic polynomial as shown below:

s(x) = A

(x − xj )3 (x − xj )2 (x − xj ) + B + +C +D 3 2 hj hj hj

where xj is the lower end of the interval containing x, and hj = xj+1 −xj . Parameters A, B, C, and D are obtained by imposing conditions to the first derivative S 0 (x) and second derivative S 00 (x) to be the same at both sides of each data point. These conditions are applied to all points except the first and last ones, where boundary conditions are arbitrarily defined, so a system of equations is obtained. Fortunately, Python includes the scipy.interpolate module that totally automatize the process: y = float(interp1d(xdata, ydata,’cubic’)(x))

A spline finds a good way!

15

Example of Interpolation Methods Interpolation and Fitting

1.4

Example of Interpolation Methods

This example shows the different methods that were described above, applied to the same data set. 1 2 3

# # #

Interpolation Methods - Example

4 5 6

from numpy import array , poly1d , polyfit from scipy . interpolate import interp1d

7 8 9 10 11

# Your data xdata = array ([2 ,3 ,4 ,6 ,12 ,18 ,22 ,33 ,40 ,45 ,50 ,57]) ydata = array ([4.5 ,10 ,16 ,37 ,120 , 100 ,83.9 ,65 ,64 ,66 ,70 ,71])

12 13

xv = 3.5

# value to interpolate

14 15 16 17

# Linear yv_lin = interp1d ( xdata , ydata , kind = ’ linear ’) ( xv )

18 19 20 21

# Pure polynomial yv_pol = poly1d ( polyfit ( xdata , ydata , len ( xdata ) -1) ) ( xv )

22 23 24 25

# Quadratic spline yv_qspl = interp1d ( xdata , ydata , kind = ’ quadratic ’) ( xv )

26 27 28 29

# Cubic spline yv_cspl = interp1d ( xdata , ydata , kind = ’ cubic ’) ( xv )

30 31

print ( " y_lin = " , yv_lin ,

16

Interpolation and Fitting Example of Interpolation Methods 32 33 34

"\ ny_pol = " , yv_pol , "\ ny_qspl = " , yv_qspl , "\ ny_cspl = " , yv_cspl )

35

and the result is y_lin = 13.0 y_pol = 12.7535196168 y_qspl = 13.188152688568351 y_cspl = 12.74574808523611

We can see in Figure 1.1 that results may differ greatly. The result at all nodes xi is identical to the data yi but different in between.

Figure 1.1: Think twice when choosing an interpolation method!. Here, linear or cubic splines are the best options.

17

Least Squares

1.5

Interpolation and Fitting

Least Squares

The Least Squares (LS) method is not truly an interpolation method, but an artifice for smoothing and correcting experimental data. In addition, it provides a polynomial that fits the data in a consistent and smart way, and that can be used instead of the data itself as a formula, although it does not necessarily passes through all of them. It is a widely used tool in many engineering fields. The first formulations of the method of least squares dates from 1805 (Legendre and Gauss), when the power of the predictive method was shown in situations where the observational data incorporate a certain degree of error. P i Our goal is to find a polynomial Pm = m i=0 ai x of lesser degree than the pure polynomial, which passes near the points exhibiting a less oscillating behavior. Least square polynomials tend to compensate to some extent for intrinsic errors associated with data points. The a0 , ...an coefficients are determined in such a way as to minimize the quadratic error of the fitting at all the points. In matrix form:    P P P 2 P  nP+ 1 xi ... P xm i    a0  y P x2i i     m+1 P  xi     x ... ... x    i i P 2 xi y i  P m+2  a1  xi ... ... ... xi     ...  =  ...  P   ...   a     xm y   P m P m+1 P 2m  m i i xi xi ... ... xi  and solve for a . This system always has a solution, although with some caveats because small and very large quantities coexist in the same matrix. If we have n + 1 data points, and 

18

Interpolation and Fitting

Least Squares

• if m n, there are infinite solutions. Normally we have many n+1 points and use a small m-degree polynomial. The higher degree of the fitting polynomial, the closer to actual data points it runs. But keep in mind that we are not looking for a pure interpolation polynomial, but a softer, lower order polynomial, which does not oscillate, and that somehow compensates for inherent errors of the data. As a suggestion, you can represent the points in a scatter plot. Afterwards, you can try a degree that is equal to the number of trend changes plus one, and then increase the degree of LS fit. A plot with all the cases can be of great help. Many authors indicate that the best fit is the one that results in a higher regression coefficient. However, the generalization of this criterion leads to the polynomial of pure interpolation, which by definition will give the maximum adjustment of 100% passing through all the points, but that is not what we are looking for. Instead, I recommend gradually increasing the degree of the LS regression polynomial, and plotting the result to observe the behavior, not only at the data but also in the intermediate intervals. In the example below, polynomial fit was increased to an 8th degree, but beyond that, the polynomial began to exhibit an oscillatory behavior. 19

Least Squares 1 2 3

# # #

Interpolation and Fitting

Least Squares - Example

4 5 6

from numpy import array , poly1d , polyfit , arange from scipy . interpolate import interp1d

7 8 9 10

# My x data xdata = array ([2 , 3 , 4 , 6 , 12 , 18 , 22 , 33 , 40 , 45 , 50 , 57])

11 12 13 14

# My y data ydata = array ([4.5 , 10 , 16 ,37 ,120 ,100 , 83.9 ,65 , 64 , 66 , 70 , 71])

15 16 17 18 19

# Calculate all LS fits a2 = polyfit ( xdata , ydata , 2) a3 = polyfit ( xdata , ydata , 3) a8 = polyfit ( xdata , ydata , 8)

20 21 22 23 24 25

# Finer x range just for plotting xvals = arange (2 ,57 ,.5) yvals_LST2 = poly1d ( a2 ) ( xvals ) yvals_LST3 = poly1d ( a3 ) ( xvals ) yvals_LST8 = poly1d ( a8 ) ( xvals )

26 27 28 29 30 31 32 33 34 35 36

# Plot LS fits import matplotlib . pyplot as plt plt . close ( ’ all ’) # erase old plots fig = plt . figure (1) plt . plot ( xvals , yvals_LST2 , ’b - ’ , xvals , yvals_LST3 , ’r - ’ , xvals , yvals_LST8 , ’y - ’ , xdata , ydata , ’ bo ’) plt . legend (( ’ LS2 ’ , ’ LS3 ’ , ’ LS8 ’ , ’ data ’) )

37

20

Interpolation and Fitting 38 39

Least Squares

# Print results print ( ’ Coefficients are : ’ , a8 )

Coefficients are : [1.21242621 e -09 -3.31174174 e -07 3.75413629 e -05 -2.27553315 e -03 7.89102201 e -02 -1.54036561 e +00 1.51737533 e +01 -5.36623265 e +016 .55567161 e +01]

Figure 1.2: Least Squares Fit of data. LS8 fits well with no oscillation. Do not go further!

21

Least Squares

Interpolation and Fitting

22

2 | Integration 2.1

Symbolic Integration

2.1.1 Symbolic Indefinite Integrals Back in my early days of undergraduate student courses, solving integrals was a very entertaining challenge, and at the same time a sure question in the exams. There was a number of rules to find the primitive functions depending on whether the integrand was a polynomial, a rational function, trigonometric, all very tricky and uncertain. I could not imagine that there would come a day when such an artisan task could be solved with a computer with symbolic capacity.

The Plimpton table (1900 b.C.), Pythagorean triples 2 2 2 a +b =c

The Python sympy module facilitates this task as can be seen in the examples that follow. 23

Symbolic Integration

Integration

? Let us assume that we want to obtain the primitive of Z

1 2

(6x5 +

log(x) )dx x

# Symbolic Indefinite Integral example from sympy import *

3 4

x = Symbol ( ’x ’)

5 6

i1 = integrate (6* x **5 + log ( x ) /x , x )

7 8

print ( ’ Result is ’ , i1 )

9

Result is x **6 + log ( x ) **2/2

2.1.2

Symbolic Defined Integrals

? Let us try something more sophisticated such as a symbolic

definite integral expression. In this case we are combining reals with non rational and ordinal numbers. Z

b

Z cos(x) + sin(x)dx +

−π/2 1

#

0

4

from sympy import * from numpy import pi , inf

5 6 7

sin(x) √ dx x

Symbolic defined integral example

2 3



x = Symbol ( ’x ’) b = Symbol ( ’b ’)

24

Integration

Numerical Integration

8 9

i2 = integrate ( cos ( x ) + sin ( x ) , (x , - pi /2 , b ) ) + integrate ( sin ( x ) /( x *0.5) ,(x , 0 , inf ) )

10 11

print ( ’ Result is ’ , i2 )

12

Result is

sin ( b ) - cos ( b ) + 4.14159265358979

Impressive!

2.2 2.2.1

Numerical Integration Integrand is a formula

This is the most general case, in which the integrand is a mathematical expression and limits are given. In physics and engineering, it is common to calculate an extensive magnitude from an intensive magnitude (ie, mass from density), or to calculate the average of a property (i, e., conductivity, temperature ...), or perhaps to calculate an integral of a function over a multidimensional domain (area, moment of inertia,...). In many cases, performing the integration manually is not easy and the availability of numerical methods is really helpful.The reader will discover in the following lines the ease and power of the method described in this section. The scipy.integrate module includes different methods such as Gaussian and Romberg quadratures. However, we prefer quad routine, which is an implementation of the Fortran library QUADPACK for definite integrals. 25

Numerical Integration

Integration

? Let us solve the following integral: Z 0 1

#

3

ex−1 dx 2x + 1

Integrand is a formula - Example

2 3 4

from scipy . integrate import quad from scipy import exp

5 6 7 8

def Fun ( x ) : y = exp (x -1) /(2* x +1) return y

9 10

I_quad = quad ( Fun , 0 ,3)

11 12

print ( ’ Result is ’ , I_quad )

13

Result is e -12)

(1.5029081534735966 , 7.638285955657406

Both the solution of the integral and the estimated error are given in the result array.

? In this example, one of the limits of integration is infinity. Show that the result is π/2. Z ∞ 1 dx = π/2 x2 + 1 0 1

#

Improper Integral - Example

2 3 4

from scipy . integrate import quad from numpy import inf

26

Integration

Numerical Integration

5 6 7 8

def Fun ( x ) : y = 1/( x * x +1) return y

9 10

I = quad ( Fun , 0 , inf )

11 12

print ( ’ Result is ’ ,I )

13 14

# Exact result should be

pi /2

15

Result is (1.5707963267948966 , 2.5777915205989877 e -10)

Note that in the examples given above, functions were defined in a canonic way (def ... return). However, they can be written in a more compact equivalent manner: Fun = lambda x: 1/(x*x+1)

? You may also perform double and triple integrals as fol-

lows:

Z

1

Z

2 2



xy dx dy y=0 1

#

x=0

Double Integral - Example

2 3

from scipy . integrate import dblquad

4 5 6

f = lambda x , y : x * y **2 # note that x , y is the order of integration

7 8

I_box = dblquad (f , 0 , 1 , lambda x : 0 , lambda x : 2)

27

Numerical Integration 9

Integration

# outer and inner limits . Inner are integrated first

10 11

print ( ’ Result is ’ , I_box )

12

Result is (0.6666666666666667 , 2.2108134835808843 e -14)

? Even more, the limits can be variable expressions: Z

1

Z

x=0 1

#

y 2 +1

x2 y · dxdy

x=y

Limits are Variable Expressions - Example

2 3

from scipy . integrate import dblquad

4 5 6 7 8 9

I_9 = dblquad ( lambda x , y : x * x *y , 0, 1, lambda y : y , lambda y : y * y +1) # Note that y , x are the same order as dx . dy # Note that limits order is outer and inner

10 11

print ( ’ Result is I_9 = ’ , I_9 )

12

Result is I_9 = (0.5583333333333333 , 2.56811395902259 e -14)

? Yet, integrate with reverse order dydx : Z

1

x=0

Z

ex

 x + y 2 · dydx

y=0

28

Integration 1

Numerical Integration

from scipy . integrate import dblquad

2 3 4 5 6 7

I_7 = dblquad ( lambda y , x : x + y **2 , 0, 1, lambda x : 0 , lambda x : exp ( x ) ) # Note that y , x are the same order as dy . dx # Note that limits order is outer and inner

8 9

print ( ’ Result is I_7 = ’ , I_7 )

10

Result is I_7 = (3.1206152136875187 , 1.038969199265395 e -13)

Certainly, the quad function is very powerful. You can perform all sort of simple, double, and triple integrals.

2.2.2

Montecarlo

The Montecarlo integration is an algorithm to estimate an approximation to a definite integral. The method consists of generating a large number of samples, where the integrand function is evaluated. The result is summed if the sample falls inside the integration domain. In the example below, we perform the Montecarlo integral of the last example in the previous section. 1

#

Montecarlo Integration - Example

2 3

from numpy import random , exp

4 5 6

x1 , x2 = 0 , 1 # bounding box y1 , y2 = 0 , 4

7 8

# generate x , y samples

29

Numerical Integration 9 10 11

Integration

n =5000 ; sum =0 x_sample = random . uniform ( x1 , x2 , n ) y_sample = random . uniform ( y1 , y2 , n )

12 13 14 15

for i in range (0 , n ) : x= x_sample [ i ] y= y_sample [ i ]

16 17 18 19 20 21

# check if x , y inside bounds if (y >0 and y < exp ( x ) ) : inside = 1 else : inside = 0

22 23 24 25

# accumulate function when inside fun = x + y **2 sum = sum + fun * inside

26 27

I_montec = sum / n *( x2 - x1 ) *( y2 - y1 )

28 29

print ( ’ I_Montecarlo = ’ , I_montec )

30

I_Montecarlo =

3.12422911458

Note that the result is an approximation to π=3.14159...

2.2.3

Integrand is pairs of data

In engineering, many circumstances arise in which, instead of an analytical function, only lists of pairs of values (x, y) are available. This is the normal case of tables of mechanical, thermophysical, or other properties. The integral can not be done with the previous methods and instead it is necessary to use the so-called numerical quadratures, in which the integral is 30

Integration

Numerical Integration

replaced by a weighted sum: Z b n X [{X} → {Y }] · dx ' wi · f (xi ) a

0

Some quadratures are based on interpolation and others based on adaptive polynomials. Among the first, the most known and used are those of sum of rectangles by intervals, sum of trapezoids by intervals, Simpson’s rule (polynomials of order 2 in equispaced points), Newton-Cotes quadratures (equispaced trapezoids), and Gaussian qua-dratures (with variable integration points). The use of these quadratures is appropriate when the integration points or nodes coincide with data, or when data are equispaced, but this is not always the case. Another difficulty that may arise is that the integration limits may not coincide with any of the known points xi . In this section we propose to use a mixed method that exploits the power of Python with scipy.integrate.quad and scipy.interpolate.splines. In the example below, we calculate the average density of vapor in a range of temperatures, assuming both linearity and splines for smoothness. Unless there are solid reasons to assume that the behavior is purely linear, it is more practical to assume that the transition is smooth and the spline method is the one that will give the most accurate results. 1

#

Integrate Arrays - Example

2 3 4 5

from scipy . integrate import quad from scipy . interpolate import interp1d from numpy import array

6 7

# Temperature of vapor , DC

31

Numerical Integration 8

Integration

x1 = array ([100 ,130 ,170 ,190 ,230 ,270 ,320 ,370])

9 10 11 12

# Density of saturated steam , kg / m3 y1 = array ([.598 ,1.496 ,4.122 ,6.397 , 13.99 ,28.09 ,64.72 ,203.0])

13 14

# 1- Mean density asuming LINEARITY

15 16

17

I_lin = quad ( lambda x : interp1d ( x1 , y1 , ’ linear ’) ( x) ,150 ,300) Mean_lin = I_lin [0] /(300 -150)

18 19

# 2- Mean density asuming SMOOTHNESS

20 21

22

I_splines = quad ( lambda x : interp1d ( x1 , y1 , ’ cubic ’)( x ) , 150 ,300) Mean_splines = I_splines [0] /(300 -150)

23 24 25

print ( ’ Mean_lin = ’ , Mean_lin , ’ kg / m3 ’) print ( ’ Mean_splines = ’ , Mean_splines , ’ kg / m3 ’)

26

Mean_lin = 17.30806667011904 kg / m3 Mean_splines = 16.230042258274562 kg / m3

Note that both results differ significantly. One must discern which method is more suitable according to the data type.

2.2.4

Fourier Transform

The integral known as the Fourier Transform deserves special attention for its applications in various branches of science. In the field of a time signal, this function decomposes a time function f(t) into its frequency components. 32

Integration

Numerical Integration

Figure 2.1: Data referring to Section 2.2.3. In this example, linear is fine, but smoothness (C2 continuity) looks a good assumption too!

1 fb(ω) = √ 2π

Z



f (t)eiωt

−∞

Normally, the time signal f(t) is a discrete sample so the Discrete Fourier Transform is applicable.

yk =

n−1 X

exp{−2πj

n=0

kn }fn N

In Python, all this is automatic so we call the scipy.fftpack.fft routine. One of the proposed problems in this book illustrates how to perform a Fourier analysis. Please refer to Section 6.5. 33

Numerical Integration

Integration

34

3 | Solving equations 3.1

Systems of Linear Equations

Systems of linear equations or linear systems are well known to all students from high school and college courses, and they frequently break into a multitude of engineering fields. There are many coupled physical systems that ideally obey linear laws. Therefore linear systems are a fundamental framework that we must handle many times.       a00 a01 ... a0n  x0     y0    a10 a11 ... a1n    ..     y1     . =  ..  ..    .  .            an0 an1 ... ann xn yn  There are many methods of solution: row reduction, elimination of variables, matrix solution, Gaussian elimination, ... Examples appear even in the user manuals of use of hand calculators. This book includes a self-explanatory example of the use of the coefficient matrix with two methods: The numpy.linalg.solve library and by matrix inverse. 35

Systems of non-linear Equations 1

#

Solving equations

System of linear equations

2 3 4

from numpy import array , matmul from numpy import linalg

5 6 7 8 9

my_matrix = array ([[1 , 2 , 5 ,6] , [4 , -4 , -6 , 8] , [ -12 , 1 , 3 , 9] , [18 , 0 , 0 , 6]])

10 11

my_vector = array ( [1 , 6 , 7 , 2])

12 13

solution = linalg . solve ( my_matrix , my_vector )

14 15

print ( ’ Solution is x1 , x2 , x3 , x4 = ’ , solution )

16 17 18

# Alternate method solution1 = matmul ( linalg . inv ( my_matrix ) , my_vector )

19 20

print ( ’ Solution is x1 , x2 , x3 , x4 by inv [ A ]* b = ’ , solution1 )

21

Solution is x1 , x2 , x3 , x4 = [ -0.18245614 3.27368421 -2.12982456

0.88070175]

Solution is x1 , x2 , x3 , x4 by inv [ A ]* b = [ -0.18245614 3.27368421 -2.12982456 0.88070175]

Of course, both solutions are identical. 36

Solving equations

Systems of non-linear Equations

First occurrence of E = mc2 by A. Einstein. Photo by Peat Bakke

3.2

Systems of non-linear Equations

Sooner or later, engineers and scientists encounter one or more nonlinear equations whose solution is not immediate because the unknown variables can not be cleared and the solution can not be obtained easily by substitution or another direct method. In these cases we can follow an iterative method in which we start with a first guess and then we approach the solution by successive approximations. The most well-known methods to find solutions by successive approximations of a non-linear equation or system are fixed-point iteration, the secant method, and the Newton-Raphson method. The later is described next.

3.2.1 Newton-Raphson Let f (x) = 0 be an equation that we need to solve. After linearization, this equation becomes f (x0 ) + f 0 (x0 )(x − x0 ) ' 0 37

Systems of non-linear Equations

Solving equations

Now, variable x can be cleared to as the iterative formula. f (xn ) f 0 (xn ) In this book we recommend to use the scipy.optimize.fsolve routine, which is actually based on the Newton‘s method. In the example below we solve a truly devilish non-linear system. xn+1 ' xn −

1

#

System of NON - linear equations

2 3 4

from scipy . optimize import fsolve from numpy import sqrt

5 6 7

def Equations ( p ) : x ,y ,z ,t ,u , v = p

8 9 10 11 12 13 14 15

# Equations writen as F ( x ) =0 err1 = ( x **2 + 2) / sqrt ( y ) - 1.1 err2 = x * y /2 - 15 err3 = y - 4 + z * t **2 err4 = x + y + z / t err5 = ( x * y - z * t ) * u err6 = v - 30

16 17 18

# print ( err1 , err2 , err3 , err4 , err5 , err6 ) return err1 , err2 , err3 , err4 , err5 , err6

19 20

x ,y ,z ,t ,u , v = fsolve ( Equations ,[1 ,1 ,1 ,1 ,1 ,1])

21 22

print ( ’ Solution is x ,y ,z ,t ,u , v = ’ ,x ,y ,z ,t ,u , v )

23

Solution is x ,y ,z ,t ,u , v = 1.64320097451 18.257048567 -17.8066500834 0.894795316054 2.33469435623 e -10 30.0

38

Solving equations

Systems of non-linear Equations

Note that fsolve needs to start the iteration from a first guess, which is [1,1,1,1,1,1] in this example. Besides, in order to know the error of each equation at the end of the iterative process, you may remove the comment character in line 17. If the NR method enters zero derivative in some iteration, try another initial point and take advantage of the fsolve automatism.

3.2.2 The Secant Method Although the Newton-Raphson method is the preferred in most occasions, it may result in error if there is an inflexion, where derivative is zero or very small value. In these situations, it is advisable the use of secant method, which is essentially NewtonRaphson by replacing derivatives by secant. The recurrence formula is: xn+1 = xn − f (xn )

xn − xn−1 f (xn ) − f (xn−1 )

The secant method needs two starting values, x0 and x1 , and avoids the evaluation of the derivatives. Coding is not complicated, there are many examples on the internet.

39

Systems of non-linear Equations

40

Solving equations

4 | Differential Equations Differential equations are of great importance in science and engineering, because many physical laws and relations appear mathematically in the form of differential equations. There are homogeneous and non-homogeneous, linear and non-linear, ordinary and partial derivatives differential equations. "An equation has no meaning for me unless it expresses a thought It is a differential equation with only one of God". Srinivasa independent variable, usually time. In or- Ramanujan

4.1 Ordinary Differential Equations

der to solve a set of ordinary diferential equations, you write it in the form

y (n) = F (t, y, y (1) , ..., y (n−1) ) The study of ordinary differential equations and their solu41

Ordinary Differential Equations

Differential Equations

tion is a matter of entire courses at the university. It is a complete discipline of Calculus where it is approached with different techniques such as direct integration, separation of variables, linearization, Fourier series, and Laplace transforms. In this book the scipy.integrate.odeint numerical method is used, which relies in lsoda from the general FORTRAN library odepack. ? Integrate ODE from 0 to 15, starting in x=2, y=3 (Note that the ODE includes a non-linear term). x˙ = x − y +

xy 1000

y˙ = 6x − 2y + 9 1

#

System of Differential Equations - Example

2 3

from scipy . integrate import odeint

4 5

from numpy import arange

6 7 8

# set a time scale t = arange (0 ,15 ,0.1)

9 10 11 12 13 14 15

# Define ODE system def derivatives ( state , t ) : x , y = state x_dot = x - y + 2 + x * y /100 y_dot = 6* x - 2* y + 9 return [ x_dot , y_dot ]

16 17 18

# Solve the ODE system solution_x_y = odeint ( derivatives , [2 ,3] , t )

19

42

Differential Equations 20 21 22

Ordinary Differential Equations

# Unpack variables x and y x = solution_x_y [: ,0] y = solution_x_y [: ,1]

23 24 25

# Draw phase plot and run plot import matplotlib . pyplot as plt

26 27

plt . close ( ’ all ’)

28 29 30

fig = plt . figure (1) plt . plot ( x [0] , y [0] , ’o ’ ,x ,y , ’r ’)

31 32 33 34 35

plt . title ( ’ Phase Diagram ’) plt . xlabel ( ’x ’) plt . ylabel ( ’y ’) plt . legend (( ’ start ’ , ’ run ’) )

36 37 38 39 40 41 42

fig = plt . figure (2) plt . plot (t ,x , ’ -- ’ ,t , y ) plt . title ( ’x and versus time ’) plt . xlabel ( ’ time , s ’) plt . ylabel ( ’x and y ’) plt . legend (( ’x ’ , ’y ’) )

43

43

Partial Differential Equations

4.2

Differential Equations

Partial Differential Equations

Laws of conservation of mass, energy, momentum, and other magnitudes such as electric charge, probability, stress and strain, 44

Differential Equations

Partial Differential Equations

are normally described with partial differential equations (PDE). What makes PDE very special is that the solution depends on the space, and possibly on time, i.e. multiple independent variables. There are elliptical equations (for example the Laplace and Poisson equations), parabolic equations (heat equation), and hyperbolic equations (wave equation) and are conditioned or prescribed by a series of Dirichlet or Newmann type boundary conditions. To solve differential equations in partial derivatives with numerical methods there are several techniques: finite differences, finite elements, finite volumes, ... In this book only an example of the first method is given, since the other two are beyond the scope of this book due to their complexity.

4.2.1

Finite Differences

Let us illustrate the method with a simple exercise. We want to solve the Laplace equation in a squared geometry which is 16x16 cm. The boundary conditions are: 20ºC along west and south borders, 250 ºC along north, and no heat transfer (adiabatic) at the east border. ∂ 2T ∂ 2T + = 0. ∂x2 ∂y 2 After replacing space derivatives by finite differences, the equation above becomes: Ti+1,j − 2Ti,j + Ti−1,j Ti+1,j − 2Ti,j + Ti−1,j + =0 (∆x)2 (∆y)2 45

Partial Differential Equations

Differential Equations

Here the central scheme is used, it can be generalized to any differentiation scheme. 1

#

Partial Differential Equations - Example

2 3

from numpy import meshgrid , arange , full

4 5 6 7

# Build a mesh X , Y = meshgrid ( arange (0 , 50) , arange (0 , 50) )

8 9 10 11

# Initialize U0 = 30 # first guess U= full ((50 , 50) , U0 , dtype = float )

12 13 14 15 16 17

# Boundary contitions Unorth = 80 Usouth = 20 Uwest = 20 Ueast = 0

18 19 20 21 22

U [49: ,:] = U [:1 ,:] = U [: , :1] = U [: , 49:] =

Unorth # Dirichlet Usouth # Dirichlet Uwest # Dirichlet Ueast ; U [: , 48] = Ueast

# Neumann

23 24 25 26 27 28 29 30

31 32

# Iterate ii =0 dxy = 1 while ii < 200: for i in range (1 , 49 , dxy ) : for j in range (1 , 49 , dxy ) : U [i , j ] = ( U [i -1 , j ] + U [ i +1 , j ] + U [i , j -1] + U [i , j +1]) /4 ii +=1 U [: , 48] = Ueast

33

46

Differential Equations 34 35 36 37 38

Partial Differential Equations

# Contour plot of the solution U(x ,y) import matplotlib . pyplot as plt plt . contourf (X , Y , U , 25 , cmap = plt . cm . jet ) plt . colorbar () plt . show ()

39

Temperature distribution in the plate, ºC

4.2.2 Finite Elements and Finite Volumes The finite difference method described above currently has a more academic than practical utility. There are formulations in finite differences that try to contemplate non regular geometries but with little success. Currently, advanced numerical methods such as the Finite Element Method (FEM) and the Finite Volume Method (FVM) are used in engineering. Although both methods are applicable to any system of differential equations in multi-physical partial derivatives, the use of FEM is more consolidated for problems of structural analysis, elastic 47

Partial Differential Equations

Differential Equations

field and heat transfer, while FVM takes advantage of Gauss theorem to simplify integral equations when possible to apply, and is more dedicated to fluid mechanics (Navier Stokes). There are formulations of both types for the Maxwell equations, gravitational field, etc. A detailed description of these methods is out of the scope of this introductory book, and the reader is invited to explore the capabilities of Python applications that use this type of numerical methods. • FEniCS. The FEniCS Project Version 1.5 M. S. Alnaes, J. Blechta, J. Hake, A. Johansson, B. Kehlet, A. Logg, C. Richardson, J. Ring, M. E. Rognes and G. N. Wells Archive of Numerical Software, vol. 3, 2015, [DOI] Automated Solution of Differential Equations by the Finite Element Method A. Logg, K.-A. Mardal, G. N. Wells et al. Springer, 2012. See https://fenicsproject.org/

• SfePy. R. Cimrman. SfePy - write your own FE application. In P. de Buyl and N. Varoquaux, editors, Proceedings of the 6th European Con- ference on Python in Science (EuroSciPy 2013), pages 65–70, 2014. http://arxiv.org/abs/1404.6391.

• FiPy. J. E. Guyer, D. Wheeler and J. A. Warren, “FiPy: Partial Differential Equations with Python,” Computing in Science and Engineering 11 (3) pp. 6-15 (2009). See https://www.nist.gov/publications/ finite-volume-pde-solver-using-python-fipy

48

5 | Mathematical Statistics Whenever we perform an experiment in which we observe some quantity (strength, number of defects, weight of people,etc.) there is associated a random variable xdata. In Statistics we draw conclusions about the population from properties of samples . We do this by calculating point estimates, confidence intervals, upper and lower bounds, inferring a fitting Cora Ratto de Saddistribution, and other relevant paramet- osky ers. In these lines, we will just tiptoe around a few essentials in this matter. For advanced use, Python libraries provide a very complete suite of functions, tests, and routines to deal with almost any need for the statistics researcher.

5.1

Mean and Standard Deviation

Mean and variance of a sample are defined by 49

Mean and Standard Deviation

Mathematical Statistics

n

1X x¯ = xj n j=1 n

1 X (xj − x¯)2 s = n − 1 j=1 2

Standard deviation is just the square root of variance. Both sample mean x¯, and sample variance s2 , are point estimates of the population mean µ, and population variance σ2. 1

#

Sample Statistics - Example

2 3

from statistics import *

4 5 6 7 8 9 10 11 12 13 14

# Sample data xdata = [10.7 , 10.9 , 8.6 , 8.2 , 11.8 , 9.9 , 6.6 , 9.8 , 10.1 , 10.1 , 9.8 , 12.3 , 8.5 , 12.1 , 11.0 , 9.2 , 9.2 , 7.1 , 11.8 , 6.0 , 14.2 , 10.0 , 13.1 , 9.0 , 11.6 , 9.6 , 8.5 , 10.2 , 9.1 , 9.3 , 7.5 , 10.2 , 10.2 , 9.6 , 8.0 , 11.8 , 9.7 , 7.3 , 8.2 , 10.0 , 10.5 , 11.1 , 9.1 ,10.2 , 7.5 , 11.3 , 9.8 , 7.9 , 8.4 , 6.8 , 7.0 , 12.4 , 8.9 , 7.0 , 9.8 , 10.4 , 10.0 , 9.3 , 10.0 ]

15 16 17 18 19

# Sample parameters x_sample = mean ( xdata ) s_sample = stdev ( xdata ) n = len ( xdata )

20 21 22 23

print ( ’ Results are : ’) print ( ’ x_sample = ’ , x_sample ) print ( ’ s_sample = ’ , s_sample )

50

Mathematical Statistics 24

Confidence Limits of µ and σ 2

print ( ’n = ’ ,n )

25 26 27 28 29 30 31

# Plot histogram import matplotlib . pyplot as plt plt . hist ( xdata ) plt . title ( " Histogram of xdata " ) plt . xlabel ( " Value " ) plt . ylabel ( " Frequency " )

32

Results are : x_sample = 9.63050847457627 s_sample = 1.6984023158989985 n = 59

Figure 5.1

5.2

Confidence Limits of µ and σ 2

In general, the point estimates of the population mean and variance are not sufficient, and it is desired to estimate each para51

Confidence Limits of µ and σ 2

Mathematical Statistics

meter within a range that covers a high percentage of the possible values. These are the Confidence Limits. Assuming that our data come from a Normal distribution, s s x¯ − t α2 √ ≤ µ ≤ x¯ + t α2 √ n n (n − 1)s2 (n − 1)s2 2 ≤ σ ≤ χ2α χ21− α 2

2

where t and χ are the Student and Chi2 distributions, and α is the significance level (probability of taking a bad decision), typically 5 %. 2

1

# ... continuation of the script above

2 3 4

from scipy . stats import t , chi2 from numpy import sqrt

5 6 7

# significance level alpha = 0.05

8 9 10 11 12

# Confidence intervals for the pop . mean tstudent = t . ppf (1 - alpha /2 ,n -1) mu_max = x_sample + tstudent * s_sample / sqrt ( n ) mu_min = x_sample - tstudent * s_sample / sqrt ( n )

13 14 15

16

# Confidence interval for the population std dev Smin = sqrt (( n -1) * s_sample **2/ chi2 . ppf (1 - alpha /2 , n -1) ) Smax = sqrt (( n -1) * s_sample **2/ chi2 . ppf ( alpha /2 ,n -1) )

17 18 19 20

print ( ’ Confidence Intervals are : ’) print ( mu_min , ’

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